NTU Singapore Space Projects: Launch of Three New Initiatives Including First AI Nanosatellite Under National Space Push

Singapore's Bold Leap into Space: NTU's Three New Projects Under National Push

Nanyang Technological University, Singapore (NTU Singapore), has announced the launch of three innovative space projects as part of the country's Space Access Programme (SAP). This initiative falls under the broader Space Technology Development Programme (STDP) spearheaded by the Office for Space Technology and Industry (OSTIn). With the Singapore government committing over S$200 million since 2022 to bolster the space sector, these projects mark a significant step in positioning the city-state as a key player in the global space economy. 71 70 The projects emphasize rapid development of smaller, agile satellites, focusing on artificial intelligence (AI), advanced propulsion, and high-resolution imaging—technologies with dual-use potential for commercial and national applications.

NTU's Satellite Research Centre (SaRC), the birthplace of Singapore's satellite programme since the first XSAT launch in 2011, leads these efforts. Over the past two decades, SaRC has designed, built, tested, and operated more than nine satellites, establishing NTU as a hub for space education and research in a non-spacefaring nation. 68 Professor Warren Chan, Dean of NTU College of Engineering, highlighted the evolution: "This new programme reflects how space technologies are evolving towards faster development and smarter operations."

These initiatives align with Singapore's national space strategy, which includes establishing the National Space Agency of Singapore (NSAS) on April 1, 2026. The strategy aims to foster innovation, secure economic interests, and address national imperatives like environmental monitoring and urban planning through space tech. 64

The First Project: Pioneering AI Nanosatellite with Edge Computing

At the forefront is Singapore's inaugural AI-powered nanosatellite, a 3U CubeSat measuring 30cm x 10cm x 10cm and weighing under 5kg. Developed in collaboration with Satoro Space for the satellite bus and NTU SaRC for the payload, this sub-satellite integrates edge-computing AI to process imagery directly in orbit. 71 69

Traditional satellites downlink massive raw data volumes—hundreds of megabytes to gigabytes per image—straining bandwidth and delaying analysis. Here, compact AI models analyze images onboard, identifying events like forest fires, oil spills, or disaster zones. It filters irrelevant data (e.g., cloud-covered areas) and transmits concise outputs: coordinates, summaries, and snippets in kilobytes to megabytes. SaRC Executive Director Lim Wee Seng explains: "Instead of sending everything back to Earth, the satellite can make decisions on board—filtering, analysing, and transmitting information, not just raw data." This slashes latency, optimizes bandwidth, and enables real-time insights for time-critical responses. 70

The satellite also tests next-generation perovskite solar cells, lightweight panels printable on flexible materials, developed by NTU's School of Electrical and Electronic Engineering (EEE), School of Materials Science and Engineering (MSE), and startup Singfilm. These promise cheaper, efficient power for future smallsats. Scheduled for a 2026 launch into a 500km sun-synchronous orbit, the one-year mission will validate electronics and operational design. 71

Maverick Shih, Chairman of Satoro Space, noted the synergy: "The cooperation... allows us to build up proven CubeSat solutions and implement cutting-edge space technology rapidly." For researchers eyeing AI-space fusion, opportunities abound at research jobs in higher ed.

Project Two: Advancing In-Orbit Mobility with Propulsion and Material Testing

The second project features a larger 16U nanosatellite (40cm x 30cm x 30cm, up to 30kg) dedicated to propulsion and environmental durability testing. It houses the MUlti-Stage Ignition Compact (MUSIC) engine from NTU spin-off Aliena, which ionizes gas propellant and accelerates ions via electric/magnetic fields for precise, efficient thrust—ideal for orbit adjustments in crowded low Earth orbit (LEO). 71 69

Complementing this is an Atomic Oxygen Detector from NTU Temasek Laboratories, targeting atomic oxygen—a highly corrosive gas in Very Low Earth Orbit (VLEO, below 450km). This tests advanced materials' resilience, crucial for sustainable satellites amid rising orbital congestion. Aliena's CEO Dr. Lim Jian Wei, Mark, emphasized: "Advanced in-orbit mobility... opens up new mission possibilities... for satellite constellations to operate effectively and sustainably." 71

With a planned 2028 deployment and 1.5-year mission, this project builds on Aliena's 2022 in-orbit demo via SpaceX. It underscores spin-offs' role in commercialization, inspiring postdocs and faculty. Explore postdoc positions in propulsion tech.

Project Three: High-Resolution Earth Observation via ISS LEOCAM

Rounding out the trio, the LEOCAM (Lightweight Electro-Optical Camera) payload employs a novel triple-mirror design—eschewing lenses—for superior resolution, capturing ground features ≥1m wide. Developed by LightHaus Photonics, it will validate performance on the International Space Station (ISS) in 2027 for a six-month stint. 71 70

This mirror-based system reduces weight and aberration, enhancing Earth observation for urban planning, disaster management, and climate monitoring. Dr. Phua Poh Boon, LightHaus CTO, called it "a key milestone... the first Singaporean company to build a space-based optical system." Such tech could spawn applications in Singapore's smart nation vision.

Read the full NTU announcement for visuals and specs. 71

NTU SaRC: Legacy of Innovation in Singapore's Space Journey

Established as the cradle of Singapore's space endeavours, SaRC has launched nine satellites by 2020, from 1U CubeSats to 100kg platforms. Milestones include XSAT (2011), the world's first nanosat with chip-scale atomic clock (2019), and low-light cameras. Today, it operates 24/7 mission control and ground stations, blending academia with industry. 68

• XSAT: Singapore's first satellite, tech demo.
• AOBA VELOX-IV: Glowing success in propulsion.
• SCOOB-I: 10th NTU satellite (2022).

SaRC's interdisciplinary approach trains students via hands-on programmes, producing talent for research assistant jobs. Its spin-offs like Aliena exemplify university-industry translation.

Partners Driving Commercialization and Ecosystem Growth

These projects showcase collaboration: Satoro Space (satellite-as-a-service), Singfilm (materials), Aliena (propulsion), LightHaus (optics). Funded via SAP's streamlined access to launches (2026-2028), they aim for "space heritage"—proven in-orbit performance—to attract investors.

Singapore's space sector, valued at billions globally, leverages strengths in AI and robotics. STDP 2.0 (from 2025) adds S$60m for R&D. For academics, this means grants, patents, and startups. Check Singapore university jobs for openings.

Details in Tech in Asia coverage. 69

Implications for Higher Education and Research Careers

In higher ed, these projects elevate NTU's profile, attracting global talent. Students gain exposure to real missions, boosting employability in burgeoning fields like space AI. Faculty secure funding for interdisciplinary work—EEE, MSE, Temasek Labs collaborate seamlessly.

Challenges include orbital debris and VLEO corrosion, addressed via detectors and propulsion. Solutions foster sustainable constellations for telecom, EO. For career seekers, Singapore's push creates demand: lecturers in aerospace, professors in AI-space. Visit lecturer jobs and professor jobs.

Challenges, Solutions, and Broader Impacts

• Bandwidth Limits: AI edge processing reduces data load by 90%+.
• Power Constraints: Perovskite cells offer higher efficiency.
• Sustainability: Propulsion enables deorbiting, detectors inform materials.

Earth benefits: faster disaster response, precise monitoring. Economically, commercialized tech could export Singapore innovations. See Straits Times analysis: Singapore's first AI nanosatellite. 70

Future Outlook: Towards a Thriving Space Ecosystem

With annual SAP launches through 2028 and NSAS launch, expect more missions. Commercialization in "a few years," per experts. Singapore eyes inter-satellite lasers (Transcelestial, 2026), Earth observation initiatives.

For students/professionals, this signals growth in space careers. Tailor your CV with academic CV tips. Rate experiences at Rate My Professor.

Photo by Sraboni Basu on Unsplash

Getting Involved: Opportunities in Singapore Space Research

Prospective researchers: Join NTU programmes, apply for STDP grants. Job hunters: Platforms like higher ed jobs, university jobs, career advice. Post a vacancy at /recruitment or explore post a job.

These projects exemplify how universities drive national innovation—stay tuned for launches.